TECHNICAL FIELD
[0001] The present invention relates to the field of molecular biology and method of altering
the genetic material of a cell or organism. In particular, the invention relates to
the use of retrotransposons as vectors suitable for the expression, at various levels,
of genetic material. The present invention has a wide variety of applications, for
example, in animal and plant breeding and in the understanding and treatment of various
genetic and viral diseases.
BACKGROUND ART
[0002] Various methods are currently being used in genetic engineering to enable the transfer
and expression of genes into the genomes of cells and organisms. Genes have been transferred
by incubating cells with DNA, possibly in the presence of chemicals such as polyions
or calcium phosphate. Genetic material can also be injected into the nucleus or cytoplasm
of cells or zygotes. Other methods include electroporation, liposome mediated gene
insertion, asialoglycoprotein gene insertion, particle acceleration and viral transduction.
[0003] The use of viruses in the transduction method has been shown to be very efficient
when retroviruses are used. Foreign genes are inserted into either a replication defective
or replication competent viral vector construct (usually as a plasmid), and are transferred
into cells containing all the genes necessary for packaging and replication of the
virus. Special cell lines ("helper" or viral packaging cells) have been constructed
which enable defective (non-replication competent) viral vectors to be packaged into
infectious particles or virions. The vectors themselves do not harbour the necessary
genes for replication so that when the vectors infect cells, the vectors replicate
using the enzymes in the viral particle to insert themselves into the host genome
(chromosomes). The vectors are unable to replicate further because the essential viral
genes were (hopefully) left behind in the "helper" cell. This technique has been adopted
and approved for the first human gene therapy trials, despite ongoing debate about
the safety of such usages.
[0004] Transduction by RNA tumor viruses (retroviruses) has special appeal because it can
be rapid, efficient, and results in stable integration of a small number of copies
(usually 1-2) of genetic information. Unlike transformation, retroviral integration
takes place in a precise fashion, usually at an exact position within the viral genome,
and insertion can occur at many places within the host cell genome.
[0005] Unfortunately, retroviruses are accompanied by adverse pathogenic and oncogenic effects.
However, the infectivity of retrovirus vectors can be controlled by using genetically
disabled forms in conjunction with helper cells. In order to function effectively
as a vector, the portions of necessary genetic information removed from the disabled
vector must be provided'"in trans" (by another gene, located outside the vector).
Many such helper cell lines containing, viral functions necessary for packaging, replication,
delivery, and reinsertion of replication defective viral vectors have been put into
use for the several tumor virus types commonly used. These useful viruses include
the disease organisms causing murine leukemia virus (MLV), spleen necrosis virus (SNV),
avian leukosis virus (ALV), and reticuloendotheliosis virus (REV). Patents have issued
for helper cell lines for MLV and REV (Miller, U.S. Patent No. 4,861,719; Temin et
al., U.S. Patent No. 4,650,764).
[0006] MLV viruses have become the vectors of choice for animal genetic engineering of cells
and organisms, because of their compatibility with a wide variety of animal cell types
including certain germ cells as well as human cells. MLV was used to insert viral
transgenes into the mouse germline, creating a transgenic mouse (Jaenisch et al.,
Proc. Nat. Acad. Sci. (USA)
73:1260 (1976) and Cell
24:519 (1981)). MLV vector systems have been approved for limited human gene therapy
trials despite some of the problems described above.
[0007] While retroviruses are becoming important tools for the transfer of genes into cells
there are major problems associated with retroviral vectors. One such problem is the
ability of disabled viral vector sequences to recombine with either helper viral sequences,
or sequences in the cellular genome, yielding infectious viral particles. This problem
has been dealt with by removing more viral sequences from vectors, as well as by introducing
multiple mutations and rearrangements in helper sequences. Together, these alterations
make it more difficult for the vector to revert to replication competency, but may
also lower the viral titre or infectivity. However, recombination events are common
in retroviruses (Temin, H.M., Genome
31:17-22 (1989)), and hence reversion and recombination persist to be problems.
[0008] Another difficulty associated with RNA tumor viruses is that they tend to be oncogenic.
Included in this class are the commonly used MLV vectors which cause neoplasms of
various sorts by at least two mechanisms: (1) by activating transcription of nearby
cellular oncogenes (cancer genes) due at least in part to powerful enhancerpromoter
sequences in the viral transcriptional control region, and (2) by recombining with
cellular oncogenes, which then become a part of the viral genome, causing rapid oncogenesis
that is borne along with the virus.
[0009] An additional problem associated with the use of amphotropic (broad host range) vectors
such as those being currently proposed for human gene therapy is that the amphotropic
vectors might recombine with another retrovirus in the human or animal host, yielding,
for example, amphotropic AIDS (AIDS virus able to infect a broad human host range).
The possibility theoretically exists for an amphotropic AIDS virus (HIV) arising by
recombination or by phenotypic mixing with amphotropic MLV to initiate an epidemic
by greatly expanding the range of human cells in which the HIV virus could replicate.
[0010] Thus, it is important to assure that non-replication competent MLV vectors used in
gene therapy will have a low potential for reversion or pathogenic effects. Ideally,
trans-acting viral genes should be completely isolated from vectors, and vectors should
be of non-MLV origin, nonpathogenic, nononcogenic, and bear as little homology to
MLVs as possible in order to limit productive recombination which would yield replication
competent virus. To be additionally useful for transgenic work, the vectors should
be compatible with long-term residence in the genome of the host organism.
[0011] The present invention thus relates to the use of natural, mobile cellular genes (retrotransposons)
as candidates for gene engineering vectors. Until the present invention, retrotransposons
have not been implemented in a practical forum for such uses as animal gene insertion
or gene therapy. In contrast, the research is concentrated in other areas. For example,
a neomycin phosphotransferase gene as well as the yeast trpl gene in yeast have been
amplified after introduction of the genes in a yeast GALI-Ty fusion construct (Boeke
et al., Science,
239:280-282, 1988). This involved transposition via Ty element-mediated transposition.
Others have developed a means for targeting fusion proteins into yeast Ty retrotransposon
particles which can then be harvested and presumably used for the production of antibodies,
vaccines, protein purification, diagnostics, and the like. See for example, the Adams
et al., U.S. Patent No. 4,918,166. Nonretro transposons (P elements) have also been
used for genetic transposition in the fly Drosophila, see for example, the Rubin et
al., U.S. Patent No. 4,670,388. This involves the insertion of DNA material between
defined sequences recognized by transposase, inserting the material into a Drosophila
germ cell, and causing the transposable element to be affirmatively inserted into
the genome of the recipient Drosophila insect so as to become part of the heritable
genome of the insect, wherein the element and foreign DNA can function. Mammalian
gene transfer and transgenics is discussed in the Wagner et al., U.S. Patent No. 4,873,191,
1989. This involves introducing exogenous genetic material into a pronucleus of a
mammalian zygote by microinjection. The zygote is capable of development into a mammal,
and the genetic material includes at least one gene and a control sequence operably
associated therewith. Thus, a genetically transformed zygote is obtained. The embryo
or zygote is transplanted to a pseudopregnant female and the embryo is allowed to
develop to term, wherein the genes are integrated and expressed. This approach is
entirely physical and does not involve retrotransposable elements (retrotransposons
do not require micro injection). The earliest apparent use of retroviruses to infect
the germ line was by Jaenisch et al., Proc. Nat. Acad. Sci. (USA)
73:1260 (1976) and Cell
24:519, (1981). In addition, the Vande Woude et al., U.S. Patent No. 4,405,712, describes
certain vectors derived from Murine leukemia-sarcoma viruses, and the process of transfecting
them into cells, selecting phenotype, and then superinfecting cultures in order to
obtain replication competent virus with the vectors packaged as pseudotype. These
vectors, and the methods described, are quite primitive by todays standards, and do
not involve retrotransposon vectors.
[0012] Thus, it is clearly advantageous to develop a new, efficient method for the introduction
of cellular mobile elements into the genomes of many species. The uses of such method
includes, for example, vectors for studies of gene expression in cultured cells, vectors
for transgenic organism production and vectors for human gene therapy.
DISCLOSURE OF INVENTION
[0013] The present invention relates to a process or procedure for using retrotransposons
as vectors in genetic engineering. The retrotransposons or "jumping genes" are cellular
movable genetic elements. The retrotransposons are of non-replication competent cellular
origin, and are capable of carrying a foreign gene. The retrotransposons can act as
parasites of retroviruses, retaining certain classical hallmarks, such as long terminal
repeats (LTR), retroviral primer binding sites, and the like. However, the retrotransposons
usually do not contain functional retroviral structure genes which would normally
be capable of recombining to yield replication competent viruses. Some retrotransposons
are examples of so-called "selfish DNA", or genetic information which encodes nothing
except the ability to replicate itself. The retrotransposon may do so by utilizing
the occasional presence of a retrovirus or a reverse transcriptase within the host
cell, efficiently packaging itself within the viral particle, which transports it
to the new host genome, where it is expressed again as RNA. Whatever information is
encoded within that RNA is potentially transported with the jumping gene.
[0014] Transduction of exogenous genetic information into cells or organisms is attained
by first placing the exogenous genes and/or their controlling elements into a retrotransposon
genetic element (cellular movable genetic element with long terminal repeats). The
LTR and flanking region consists of a genetic entity (RNA or DNA) which contains signals
necessary for replication, packaging, insertion, and expression of the genetic element
in a host cell as a parasite of retroviral gene transduction. The recombinant retrotransposon
is then transfected or otherwise introduced into cells providing retroviral (or retrovirus-like)
replicative functions, such as virus producing cells, or else so-called helper cells.
The retroviral trans functions combine with RNA transcripts made from the DNA copies
of the recombinant retrotransposons to form infectious retrotransposon particles or
virions. These retrotransposon particles transduced into the new host cell are reverse
transcribed into DNA, and are introduced stably into the new host genome, from which
RNA transcripts can again be generated from either the retrotransposon transcriptional
unit or from inserted internal transcriptional units, directing the expression of
useful genes. The introduced genes are unable to replicate further in the absence
of helper functions.
[0015] The invention can be utilized for gene therapy, gene insertion and expression studies
in cell culture, for the generation of transgenic animals, and in other instances
where traditional RNA tumor virus vectors may be considered unsafe or undesirable.
DESCRIPTION OF FIGURES
[0016] Fig. 1 is a schematic diagram of the invention showing the genesis of cells stably
transduced by mobile element VLPNF.
[0017] Figs. 2a and 2b are restriction maps depicting gene transfer with retrotransposon
VL30 in (a) construct pVLPNF; and (b) construct pVLPNR.
[0018] Figs 3a and 3b are photographs depicting: (a) Southern blot showing DNA of mass cultures,
lane 1, and individual clones of VLPN vectors transduced into NIH3T3 cells, digested
with Eco R 1 and hybridized to 32P-radiolabelled
neo sequences; (lane 1 mass culture; 2-7 clones, VLPNF; 8 VLPNR mass culture; lane 9
VLPNR clone); and, (b) Northern blot analysis of VLPN-transduced NIH3T3 cells, showing
presumptive VL30 and PEPCK
neo RNA bands; (lane 1-2, VLPNF mass culture; lanes 3-4, 5-6, 7-8, VLPNF clones (two
lanes each); 9-10, VLPNR clone).
[0019] Figs. 4a and 4b are photographs depicting PA317 cell clones transduced with VLPNF:
(a) Southern blot of PA317 DNA digested with Xhol and hybridized to 32P-radiolabelled
neo sequences; and, (b) total RNA blots from the clones, hybridized to
neo.
BEST MODE OF CARRYING OUT INVENTION
[0020] The following definitions of biological and genetic terms will be useful in understanding
this invention:
[0021] DNA: Deoxyribonucleic acid, the genetic material of cellular chromosomes.
[0022] RNA: Ribonucleic acid, the genetic material of the RNA tumor viruses and retrotransposons
during part of the life cycle.
[0023] DNA sequence: A linear sequence comprised of any combination of the four DNA monomers.
The DNA monomers, nucleotides of adenine, guanine, cytosine and thymine, code for
genetic information, including coding for an amino acid, a promoter, a control or
a gene product. A specific DNA sequence has a known specific function, for example,
codes for a particular polypeptide, a particular genetic trait or affects the expression
of a particular phenotype.
[0024] Gene: The smallest, independently functional unit of genetic material which codes
for a protein product or controls or affects transcription and comprises at least
one DNA sequence.
[0025] Chimera: A hybrid gene produced by recombinant DNA technology. Genotype: The genetic
constitution of a cell or organism.
[0026] Phenotype: A collection of morphological, physiological and biochemical traits possessed
by a cell or organism that results from the interaction of the genotype and the environment.
[0027] Phenotypic expression: The expression of the code of a DNA sequence or sequences
which results in the production of a product, for example, a polypeptide or protein,
or alters the expression of the zygote's or the organism's natural phenotype.
[0028] Chromosome: A fiber or threadlike structure which is completely or partially composed
of genetic nucleic acid.
[0029] Retrovirus: A virus which requires reverse transcription of RNA into DNA at some
point during its life cycle; specifically the retroviridae, or RNA tumor viruses.
This family encompasses all viruses containing an RNA genome and RNA-dependent DNA
polymerase (reverse transcriptase).
[0030] Retrotransposon: A cellular movable genetic element which is dependent upon reverse
transcription.
[0031] Vector: Usually an agent transmitting a disease or natural genetic information; here
restricted to a genetic agent transmitting a foreign gene (DNA or RNA) construct,
unless otherwise indicated.
[0032] Genome: One set of chromosomes, haploid or diploid, for an agent or organism.
[0033] Transduction: Here limited to the transmission of viral, retrotransposon, or exogenous
(added) genes (unless otherwise indicated by means of viral particles or viral functions).
[0034] Helper Cell Line: In this context, a cell line which has been genetically engineered
or which naturally contains genes capable of generation of some or all necessary retroviral
trans-acting functions or proteins, such as reverse transcriptase, viral core proteins,
envelope glycoproteins, and/or tRNA for priming reverse transcription and the like.
Examples of helper cell lines include psi2, PA317.
[0035] Replication Competent Retrovirus: A retrovirus which bears all genes necessary for
cis and
trans functions; complete, able to replicate without additional viral functions.
[0036] Non-replication Competent (defective) retrovirus: A retrovirus which requires supplemental
functions in order to replicate, or which is unable to replicate by itself. In this
context, it usually requires
trans-acting functions such as named above.
[0037] Transgene: A foreign gene, usually inserted into a vector.
[0038] cis-acting element: Genetic element which must be located on the same piece of nucleic
acid in order to function, such as transcriptional promoter or enhance elements, primer
binding sites and the like.
[0039] trans-acting element: Genetic element which need not be located in
cis, i.e., that which may be located elsewhere, such as in the cellular genome. Examples
of
trans elements are the retroviral core protein, polymerase, and envelope glycoprotein genes.
[0040] Psi sequences: Sequences of genetic information which encode the packaging functions
which enable particles to package and transmit viral or retrotransposon RNA.
[0041] The present invention relates to a process for the transfer and expression of any
gene in a cell, organism or species using retrotransposons. Retrotransposons are a
class of retrovirus-like DNA elements which are found in the genomes of most mammals.
Retrotransposons generally maintain a structural similarity to retroviruses which
includes essential replicative elements within the DNA [such as long terminal repeats
(LTRs) and primer binding sites] but need not include the capacity to produce proteins
or particles, observable phenotype, or significant pathology. Some retrotransposons
do encode proteins which may be of significance to the cell, or to the replication
of the retrotransposon. Retrotransposons replicate and disperse themselves during
a retroviral infection, or when endogenous retroviruses or retroviral genes within
the host, or host cellular genes such as cellular reverse transcriptase are activated.
Some retrotransposons are thus a part of the so-called "selfish DNA" which occupies
a significant fraction of the genomes of man and of most species. However, there is
a broad spectrum of such elements and some may naturally bear cellular genes, or genes
related to retrotransposon function. While retrotransposons are typically compatible
with the host, until the present invention retrotransposons have not been recognized
or developed as valuable tools for gene transduction.
[0042] One class of retrotransposons is mouse VL30. The VL30 genes are a family of disperse,
middle repetitive DNA sequences. The VL30 name is derived from the fact that the VL30
elements exhibit "VirusLike" properties and produce a 30 S RNA in a variety of mouse
cells. Also, physically similar and genetically related sequences are present in the
rat genome.
[0043] Mouse VL30 genes are ~ 5 kilobase cellular genetic elements found at 100-200 copies
integrated into the chromosomes of most
mus species. The VL30 genes package into and are efficiently transmitted by murine and
primate retroviruses. VL30s and other retrotransposons maintain the structural hallmarks
of retroviruses, such as long terminal repeats, tRNA primer binding sites, and inverted
terminal repeats, which are associated with various aspects of retroviral replication.
However, the VL30 retrotransposons bear little nucleotide homology to murine retroviruses
such as MLVs, and the two VL30s sequenced appear to bear no long open reading frames.
It is therefore less likely that the characterized VL30s would recombine productively
with protein encoding regions of MLVs. However, it is also possible that VL30 packaging
signals could recombine with those of MLVs, for these signals are apparently essential
for efficient packaging of the RNA into the viral particle, and it is in this packaging
(or psi) region of the genome, together with a few base pairs at the borders of the
LTRs, where the strongest homology between VL30 retrotransposons and MLVs are found.
VL30-MLV recombination has been suggested to play a role in the rapid reversion of
mutants in which only the "psi", or packaging region, has been deleted.
[0044] One of the first helper cell lines constructed for MLV vectors, psi2, is such a recombination-prone
mutant, Mann et al., Cell
33:153159 (1983). An MLV viral genome (with a single 350bp deletion in the region bearing
packaging sequences) was stably transfected into NIH3T3 cells. One of three lines
recovered quickly reverted to replication competency. Another helper cell line, psi2,
became a useful line despite its tendency to recombine and is still in use today.
In addition to reversion of 'psi-minus' packaging mutant lines to the 'psi-plus' phenotype,
the viral genome was also passively transferred by the viral particles, although at
a much lower rate. Psi2 was the prototype for more advanced packaging or helper cell
lines, such as PA317 discussed in the Miller et al., U.S. Patent No. 4,861,719 which
contains additional mutations, making it more difficult for the
cis and
trans acting portions of the viral genome to recombine.
[0045] VL30 is naturally packaged and transmitted by psi2 cells, as well as by other MLV
and primate retroviral virions. The VL30 used in present invention contains no known
intact structural genes, but does contain psi-like sequences.
[0046] VL30s are not known to be oncogenic despite their close association with the highly
oncogenic MLVs. Experimentally, MLVs have activated many tumors and permitted the
isolation of various oncogenes, but there are no examples in which mouse VL30 genes
have participated directly in oncogenesis. Similar rat VL30 elements have been shown
to recombine with MLV during the genesis of Harvey and Kirsten MSV retroviruses (Ellis
et al., Nature
292:506-511, 1981; Roop et al., Nature
323:822-824, 1986), which induce mouse epithelial tumors. Since mouse VL30 sequences
are very actively transcribed under a variety of stimuli, they might act as insertional
mutagens by gene activation, similar to murine retroviruses. Recently, the rat VL30
sequences in Harvey sarcoma virus were shown to enhance the transcriptional activity
of the accompanying
ras gene (Velu et al., J. Virology
63:1384-1392, 1989). In turn, coexpression of
ras activates the transcription of murine VL30 (Owen et al., Mol. Cell Biol.,
10:1-9, 1990). Despite their close association with oncogenic MLV viruses, VL30s have
not been directly linked to any oncogene activation event, other than circumstantial
examples such as those described above. Therefore, the VL30s are less likely to become
involved in oncogenesis than MLV. This also explains why a large number of VL30s reside
within the mouse genome, while germline MLVs are few. By remaining benign and not
complicating the host organism with undue reverse transcription, oncogenicity, and
translational burdens, VL30s and other retrotransposons have established a niche.
Selfish DNA parasites appear to be tolerated by the host.
[0047] According to the present invention, transduction of foreign gene sequences into cells
or organisms is made possible by insertion of the foreign gene sequences into a retrotransposon
genome, and by transfection of the recombinant, transcriptionally active retrotransposon
genome into cells capable of transmitting retrotransposon RNA or DNA, preferrably
RNA (helper cells). The growth media of such cells contains infectious retrotransposon
particles whose host range (range of infectively) is determined by the helper cells,
and whose infectivity is usually limited to one round of replication. Once the retrotransposon
particles or virions so generated have entered the recipient cells, the transposon
RNA is reverse transcribed into DNA and is inserted into the genome of the recipient
cell. A preparation of recipient cells containing the retrotransposon in high and
usable yield is obtained by infecting additional recipient cells with additional,
infectious virion particles.
[0048] The integrated retrotransposon can express either the LTR promoter transcriptional
unit, and/or an internal transcriptional unit if so equipped, as RNA and, preferably,
as protein which results in a useful phenotype. The foreign genes can be transcribed
from either promoter, or potentially from a third promoter. Furthermore, without expression
retrotransposons can be used in this manner to mark a cell, species, or strain, in
order to provide a unique identifying "fingerprint". The retrotransposon can additionally
comprise genetic material which encodes at least one dominant selectable marker. Useful
selectable markers include, for example, aminoglycoside phosphotransferase (nea, G4
18, APEI), dihydrofolate reductase (DHFR), hygromycin-B-phosphotransferase (HPEI),
thymidine kinase (TK), xanthine-guanine phosphoribosyltransferase (XGPRT, gpt), chloramphenicol
acetyltransferase (CAT), luciferase, and the like. Also, the retrotransposon can additionally
comprise genetic material which encodes a peptide, antibody, antigen, hormone, or
drug which is not normally expressed in the cell, organism, or species at biologically
significant levels.
[0049] The main advantages of retrotransposons are that they are relatively nononcogenic
and nonpathogenic. Aside from insertional mutagenesis, the specific vector VL30 has
no known disease etiology or history of oncogenesis, having resided in the germline
of mice for millions of years. Such long residence, together with evidence for recent
insertion of a VL30 element into the Balb/c mouse genome (Courtney et al., J. Virol.
43:511-518, 1982) constitutes de facto evidence that VL30 is also a germline vector
for transgenesis which is potentially stable for long time periods. VL30s bearing
foreign genes are efficiently transmitted, and up to a hundred copies or more of a
gene(s) can be inserted into a cell.
[0050] The present invention is potentially useful in human gene therapy, where rare oncogene
activation events and recombinations due to MLV vector sequences can be avoided by
substituting retrotransposon vectors.
[0051] The source of genetic material transmitted in such a retrotransposon vector can be
from other organisms, clones, plasmids, and the like, or it may be synthetic. The
invention may be used to modify a species or to create a new species. It is demonstrated
herein that up to 50 or more copies can be inserted into the genome, permitting the
opportunity to introduce many genes for the purpose of multi-trait introduction, or
possibly for overexpression. Also, tandem integration may take place, and large RNA
transcripts of these multimers may be made naturally. Thus, multiple cellular genetic
elements can be introduced and expressed in tandem in RNA or as separate transcriptional
units within a single cell or organism.
[0052] Silent VL30 transcriptional units exist, which can be used to switch VL30s off after
just one round of replication due to the copying of the last LTR region during reverse
transcription. A variety of VL30 LTRs are available, which contain control elements
responsive to specific stimuli including: cellular transformation, glucocorticoids,
activators of protein kinase C, serum (epidermal growth factor) stimulation, and the
like. These can be tailored to meet the expression needs of individual applications.
Since no essential structural genes appear to be present, it is demonstrated herein
that it is possible to interrupt certain regions with foreign gene constructs without
disrupting the ability to transpose effectively. In addition, many tools and methods
of expression and vectorology used with retroviral vectors (such as deletion, double-expression,
self-inactivation, germline insertion, and the like) are also possible with retrotransposons,
since their mode of transmission and expression is similar. Existing cell lines such
as psi2 and PA317 can be used to propagate VL30 much in the same way as retroviral
vectors, the principal difference being the use of cellular "jumping gene" retrotransposons
rather than the tumor viruses which have been used in such systems to date. Further,
the use of various other types of retrotransposons will provide specialized attributes
for highly specialized gene engineering.
INDUSTRIAL APPLICABILITY
[0053] Fig. 1 is a schematic diagram which generally shows the method of the present invention
wherein cells are stably transduced by mobile element VLPNF. A plasmid clone of reverse
transcribed VL30 element NVL3 was digested with restriction endonuclease Hpal, and
a blunt-end fragment bearing the rat cytosolic phosphoenolpyruvate carboxykinase [PEPCK]
promoter and bacterial
neo gene was ligated into the restriction site. The plasmid was transfected into psi2
cells which contain retroviral helper functions (core proteins, polymerase-integrase,
and envelope glycoprotein). The VLPNF-psi2 cells produced particles bearing RNA copies
of the chimeric mobile element VLPNF, which are able to infect cells with high efficiency.
Once inside the recipient cell, the RNA was reverse transcribed into DNA, and integrated
into cell DNA, where it was expressed as RNA, and as protein expressing the neo phenotype.
A variation involves the use of replication competent virus in place of helper cells.
[0054] According to the method of the present invention, a foreign gene promoter, PEPCK
from the rat, together with a bacterial neomycin resistance gene (neo) was inserted
into a VL30 genome in various orientations. These constructs were transfected into
helper (psi2) cells. It is within the contemplated scope of the present invention
that any other replication competent virus or helper cell line can be used in the
place of the donor helper cells. From these cells, VL30 efficiently transferred the
foreign genes to NIH3T3 cells (titre 10
3-4). It is within the intended scope of the present invention that titre can be increased
by such methods as centrifugation, concentrating cartridges, use of polybrene, and
the like. It is also within the contemplated scope of the present invention that any
susceptible cell or organism can be used as recipient cells. The VL30 genes were expressed
as both RNA and as a protein, which they conferred with a selectable phenotype (G418
resistance) upon the recipient cells. It is also within the contemplated scope of
the present invention that any suitable dominant selectable marker or phenotypic selection
technique may be encoded with the retrotransposon.
[0055] A nonpermuted plasmid clone carrying the mouse VL30 retrotransposon genome was digested
with restriction endonuclease
Hpal, and was ligated to a recombinant DNA construct consisting of the rat nuclear phosphoenolpyruvate
carboxykinase [PEPCK] promoter, region extending from 355 base pairs before the start
site of transcription to 73 base pairs after the start site, followed by the entire
bacterial neomycin phosphotransferase gene, without polyadenylation signal. Two clones
were recovered which corresponded to both (forward and reverse) orientations of the
chimeric DNA construct, henceforth called VLPNF (forward) and VLPNR (reverse), respectively.
The chimeric retrotransposon PEPCKneo constructs were grown in prokaryotic plasmid
vector, pGEM3, after transfection of the DNA ligation mix into
E. coli competent cells. The plasmid DNA was harvested, and was transfected by the calcium
phosphate method (Graham et al., Virol.
52:456-467 (1973), into psi2 helper cells (Mann, et al., supra., 1983). After one day,
200, µg/ml of the drug G418 was added and growth of psi2 cells on the selective media
continued for ten additional days. Mass cultures of G418 surviving cells were grown
in media without G418, and purified media from rapidly growing psi2 cells was used
to transduce VL30 retrotransposons into such recipient cells as NIH3T3 cells, PA317
cells, and chicken embryo fibroblasts. Reverse transcriptase assay was used to ascertain
the presence or absence of helper virus in donor and recipient clones. DNA blotting
(Southern blots), and RNA blotting (Northern blots) were used (described in Maniatis
et. al., 1984, "Molecular Cloning", Cold Spring Harbor Laboratory, 1982) to determine
the identity and expression, respectively, of the inserted sequences. SI nuclease
analysis (Berk et al., cite needed) was used to determine the start site of transcription
of the internal transcriptional cassette. Reverse transcriptase assay (Goff et al.,
J. Virol.,
38:239-248, 1981) was used to determine whether cells were producing infectious virus
capable of reverse transcribing RNA.
[0056] After incubating NIH3T3 cells with media from psi2 cells expressing
neo resistance after transfection with the VLPN vectors, NIH3T3 cells were themselves
selected in G418 to see whether the selectable
neo gene was transduced by the particles.
[0057] Tables IA and IB below show Experiments which were performed to titre the transducing
power of the particles in the media. In Table IA VLPNF and VLPNR constructs were transfected
into psi2 cells and the viral supernate from psi2 clones was titred on NIH3T3 cells
and were selected for ten days with G418.
TABLE IA
| TITRE OF VLPN RETROTRANSPOSONS |
| PS12-NIH3T3: |
| contruct |
100 |
10-1 |
10-2 |
10-3 |
10-4 |
| VLPNF |
+ |
+ |
+ |
+(52) |
- |
| VLPNR |
+ |
+ |
+(20) |
- |
- |
[0058] In Table IB, the viral filtrate PA317 viral helper cells transduced with VLPNF from
psi2 cells were cloned after selection with G418, and media from these cells was used
to transduce chick embryo fibroblasts (CEF) either undiluted, or 10,000 fold diluted.
Three clones of PA317 produced a titre of 10
4 infectious units per ml, or greater.
TABLE IB
| PA31 7-CEF: |
| clone: |
100 |
10-4 |
| PA317 CEF |
|
|
| 2S |
+ |
|
| 2V |
+ |
|
| 2Y |
+ |
+ |
| 3B |
+ |
|
| 2B |
+ |
|
| 2E |
+ |
+ |
| 2G |
+ |
|
| 2L |
+ |
+ |
| 2J |
+ |
|
| 2N |
+ |
|
| IB |
+ |
|
| IC |
+ |
|
| Uncloned |
+ |
|
This experiment shows that VLPNF transduced cells when diluted a thousand fold (≥
10
3 transducing units per ml), whereas VLPNR transformed at a hundred fold dilution,
but not a thousand fold.
[0059] Clones of cells from the dilutions were isolated by preparing cells from the colonies
which formed. RNA and DNA from the recipient cells were examined by electrophoresis
and the blotting methods described above. When hybridized to the bacterial
neo gene, isolated from a gel, two RNA transcripts were clearly visable at about 6 kilobases
and 4 kilobases, the sizes predicted from the map of the VLPN clones, as seen in Figs.
2a and 2b. The larger size transcript corresponds in size to the full-length VL30
genomic RNA transcript, while the smaller transcript is the size expected from the
PEPCKneo internal transcriptional unit of clone VLPNF. VLPNR mass cultures and clones
revealed only a light smear, suggesting possible heterogeneity from the internal promoter,
with no clear VL30 transcript visable. DNA blots of cell clones infected with the
two constructs revealed
EcoRI restriction endonuclease fragments of the sizes expected, as seen in Figures 2a
and 2b, except that the mass cultures and a clone from VLPNF also bore other fragments
suggestive of multiple and/or rearranged copies of the
neo containing sequences. Since the VLPNR clone has a reversed transcriptional unit which
should be capable of making an RNA in the negative sense relative to the retrotransposon
RNA, some transcriptional interference is expected which should result in rearrangements,
deletions, and changes in transcription (Hodgson et al., unpublished results using
avian leukosis virus). In addition, since there is no polyadenylation signal known
in the reverse VLPNR chimera, it is not possible to tell where the internal
neo transcript will terminate. However, selectability of the sequences indicates that
some transcription does take place. VLPNR serves as a control for forward VLPNF experiments.
[0060] The mass cultures of VLPNF-psi2 producer cells were used to transduce the amphotropic
producer cell line PA317, which is another helper cell line with a greatly expanded
range of infectable host cells, including human cells. In order to see if multiple
VL30s could be transduced, PA317s were exposed to multiple doses of media from the
psi2 cells, which can repeatedly infect PA317s due to the different tropisms of the
two types of cells. Clones of PA317s were then isolated, and RNA and DNA from these
lines were examined. DNA from mass cultures and clones of cells transduced with VLPNF
were digested with
Xhol (see Fig. 2a), which releases the internal
neo-containing fragment. It is clear from the blot that all cells were transduced at
least once, but that a large number were repeatedly transduced, and that multiple
species of VL30 were transduced repeatedly from the psi2 producers. From visual and
digitized densitometric analysis of these films, it is estimated that the PA317 cells
were transduced with from one to about 50-100 copies during the repeated bombardment.
Some
neo-containing transductants were recovered which bore deleted, smaller sized inserts
than expected, indicating that some material had been rearranged. Nevertheless, these
cells which bore single copies of such material also expressed the
neo phenotype (G418 resistance), showing that a functional
neo gene remained. It is clear from examination of the blots shown in Figs. 3a and 3b,
however, that most of the VL30 retrotransposons which were transferred did contain
near full-length VLPN DNA. Therefore, rearrangement is a possible but not probable
event. The repeated insertion of variants of the same approximate size suggested that
clones of psi2 cells in the producer mass cultures were repeatedly producing the characteristic
rearrangements which were observed. Conversely, some of the same clones may have been
repeatedly isolated. Since the DNA had been transfected into the psi2 cells, rearrangement
could have taken place during the transfection process which carried over during transduction.
[0061] Comparison of the DNA blots with RNA blots revealed that expression also characterizes
certain types of insertion observed in the DNA blots. First, bands of approximately
6-7kb on the RNA blots mark the approximate position expected for genomic VL30 transcripts,
while higher bands are not characteristic and are not expected. Measured sizes of
approximately 13 and 19kb for these larger transcripts are about the sizes expected
if multimeric, tandem insertions of VL30 had occurred, which could be transcribed
in tandem. If this were the case, multimeric transcripts should only be observed in
those samples in which multiple transductions had occurred. Since this is the case
(see apparent single copy sequences: 2k, 21, 2m, 2n, 2o, 2t, 2v, 2y, 3a, 1a, 2d, 2e,
bearing only unique genome sizes of RNA, versus clones with multiple inserts bearing
apparent multimeric transcripts), it is speculated that tandem integration took place,
and that RNA transcripts larger than one genomes length were made therefrom. It was
also determined whether multiple insertions of VLPNF would result in elevated levels
of expression, or whether the presence of additional
cis-acting control regions in the genomic DNA of these cells would dilute the available
supply of transcription factors. Presumably each chromosomal locus has its own particular
effects upon gene expression, so a variability of results was expected. However, when
the levels of transcription were compared on the basis of measured copy number, an
inverse effect was noted suggesting that additional copies of VLPNF did not necessarily
result in an increased expression. Another interpretation is that since selection
pressure was applied, clones were selected in which those with only one copy were
also sufficiently expressed to survive along with those with multiple copies, some
of which might have been silent. Therefore, it is not yet clear whether overexpression
from the VL30 LTR is possible by inserting multiple copies with a given insert.
[0062] From an analysis of the sizes of DNA fragments observed (as shown in Fig 4a), it
is seen that the same size mutants are present in a number of diverse cell lines,
suggesting a common parentage. This implies that the mutations may have occurred prior
to generation of the RNA, and not during the present infection. This, together with
the data showing that most of the Xhol fragments (including all of the internal VLPN-PEPCK
neo material) were intact in most inserts passaged by VL30 retrotransposons, suggests
that VL30 is rather stable and able to pass intact material. Some instability is characteristic
of all reverse-transcribed material, and this was also observed. Since mouse cells
contain many copies of VL30, including several transcriptionally active VL30s, these
vectors were undoubtedly not the only VL30 material being passaged (Hatzoglou et al.,
1991, in press, Human Gene Therapy) by psi2 cells. The hydridization probe used in
these studies was derived only from the chimeric bacterial portion of the insert which
is not present in any natural VL30, or in these cells (see negative control PA317).
[0063] The data shown herein with VL30 together with other data not shown clearly reveal
high levels of expression from the LTR promoter, as well as selectable levels of expression
from the internal promoter. Both promoters can be used to express the foreign gene
sequences.
[0064] Thus, VL30 vectors can be used with already developed helper cell lines such as psi2
and PA317. VL30 maintains the integrity of the foreign genes and is capable of delivery
of individual, or large numbers (> 50) of copies of the foreign genes, easily manipulated
in the laboratory.
[0065] The present invention also contemplates the selection for high levels of expression,
concentration of VL30 particles to obtain higher titre, multiple inserts, deletion
mutagenesis to determine which sequences can be used to modify or to improve the system
for gene transfer and the like. Also, vectors can be built in which the second generation
VL30 transcriptional unit is transcriptionally silent, allowing center-stage to the
inserted transcriptional unit, and reducing the chance that VL30 would be transmitted
during a secondary infection of the host with another retrovirus.
[0066] Virtually all the techniques used to improve retroviruses can also be applied to
VL30. VL30 size permits up to 5kb of genetic information to be inserted without the
need for deleting any VL30 information (MLV particles package up to about 1Okb of
genetic information in duplicate). In addition, other types of retrotransposon may
be utilized in a similar manner as VL30. It is recognized, however, that some systems
necessitate different helper mechanisms than those used for the elements described
here.
[0067] As discussed above, it is expected that many types of genes will be appropriate for
use with a retrotransposon vector. Moreover, it is expected that other types of retrotransposons
will provide suitable as vectors. Also, the selection of a preferred host is not meant
to be limiting, and many other hosts may prove acceptable. As such, while the present
invention has been described in conjunction with a preferred embodiment and illustrative
examples, one of ordinary skill after reading the foregoing specification will be
able to affect various changes, substitutions or equivalents, and alterations to the
compositions and methods set forth herein. It is therefore intended that the protection
granted by the Letters Patent hereon be limited only by the definitions contained
in the appended claims.
1. A process for the transfer and expression of a gene in cells, organisms or species,
except the methods for treatment of the human and animal body by therapy, comprising
the steps of:
a) isolating the gene,
b) introducing said gene in a retrotransposon to provide a hybrid gene,
c) introducing the hybrid gene into a donor cell capable of packaging and transmitting
the hybrid gene into a virion, constituting a retrotransposon vector,
d) transferring the virion to a recipient cell wherein the hybrid gene replicates
by reverse transcription and is inserted into the recipient cell's genome, and
e) expressing the hybrid gene and screening for the phenotype of the hybrid gene.
2. A process as claimed in claim 1, in which a preparation of recipient cells containing
the hybrid gene in high and usable yields is obtained by infection of additional recipient
cells with the virions.
3. A process according to anyone of claims 1 and 2, in which multiple hybrid genes are
introduced and are expressed as RNA.
4. A process according to claim 3, in which the multiple hybrid genes are introduced
and expressed in tandem in RNA.
5. A process according to claim 3, in which the multiple hybrid genes are introduced
and expressed as separate transcriptional units within a single cell or organism.
6. Retrotransposon vector for expression of foreign gene sequence into cells or organisms,
obtainable by:
- insertion of said foreign gene sequence into a retrotransposon genome, and
- transfection of the recombinant, transcriptionally active retrotransposon genome
into a donor cell capable of transmitting retrotransposon RNA or DNA under the form
of particle or virion which are the retrotransposon vectors.
7. A retrotransposon vector according to claim 6, in which the vector is derived from
a murine retrotransposon VL30.
8. A retrotransposon vector according to claim 7 in which the vector is selected from
the group consisting of vectors wherein the foreign gene sequence is in forward orientation
(VLPNF), and vectors wherein the foreign gene sequence is in reverse orientation (VLPNR),
with respect to the VL30.
9. A retrotransposon vector according to anyone of claims 6 to 8, in which the donor
cell is selected from the group consisting of psi2 and PA317.
10. A retrotransposon vector according to anyone of claims 6 to 9, in which the foreign
gene is expressed by a cellular movable genetic element long terminal repeat (LTR)
promotor.
11. A retrotransposon vector according to anyone of claims 6 to 9, in which the foreign
gene is expressed by internal transcriptional units included within a chimeric cellular
movable genetic element.
12. A retrotransposon vector according to anyone of claims 6 to 11, in which the retrotransposon
additionally comprises genetic material encoding at least one dominant selectable
marker.
13. A retrotransposon vector according to claim 12, in which the selectable marker is
selected from the group comprising aminoglycoside phosphotransferase (eno, G4 18,
APH), dihydrofolate reductase (DHFR), hygromycin-B-phosphotransferase (HPH), thymidine
kinase (TK), xanthine-guanine phosphoribosyltransferase (XGPRT, gpt), chloramphenicol
acetyltransferase (CAT) and luciferase.
14. A retrotransposon vector according to anyone of claim 6 to 13 in which the foreign
gene comprises genetic material which encodes a peptide, antibody, antigen, hormone,
or drug not normally expressed in the cell, organism or species at biologically significant
levels.
15. Recipient cells obtained by the process of one of claims 1 to 5 or containing a vector
according to anyone of claims 6 to 14.
16. Pharmaceutical composition comprising a retrotransposon vector according to one of
claims 6 to 14 or obtained in the process of claims 1 to 5.
17. Process for preparing a virion comprising a retrotransposon vector according to one
of claims 6 to 14, said process comprising the steps of:
a) isolating a gene of interest,
b) introducing said gene in a vector comprising at least one retrotransposon comprising
a cellular movable genetic element with long terminal repeats to provide a hybrid
gene,
c) introducing the hybrid gene into a donor cell capable of packaging and transmitting
the retrotransposon genetic element into a virion.
18. Virion obtainable by the process according to claim 17, comprising a retrotransposon
vector comprising a hybrid gene with a retrotransposon comprising a cellular movable
genetic element with long terminal repeats.
1. Verfahren zur Übertragung und Expression eines Gens in Zellen, Organismen oder Spezies,
mit Ausnahme der Verfahren zur Behandlung des menschlichen oder tierischen Körpers
durch Therapie, umfassend die Stufen:
a) Isolierung des Gens
b) Einführung des Gens in ein Retrotransposon zur Bildung eines Hybridgens
c) Einführung des Hybridgens in eine Donorzelle, die zur Verpackung und Transmission
des Hybridgens in ein Virion in der Lage ist, welches einen retrotransposon-Vektor
darstellt
d) Übertragung des Virions in eine Empfängerzelle, in der das Hybridgen durch reverse
Transkription repliziert und in das Genom der Empfängerzelle insertiert wird, und
e) Expression des Hybridgens und Screenen hinsichtlich des Phänotyps des Hybridgens.
2. Verfahren wie in Anspruch 1 beansprucht, bei dem ein Präparat von Empfängerzellen,
die das Hybridgen in hohen und verwendbaren Ausbeuten enthalten, durch Infektion zusätzlicher
Empfängerzellen mit den Virionen erhalten wird.
3. Verfahren nach einem der Ansprüche 1 und 2, bei dem multiple Hybridgene eingeführt
und als RNA exprimiert werden.
4. Verfahren nach Anspruch 3, bei dem die multiplen Hybridgene in Tandem-Anordnung eingeführt
und als RNA exprimiert werden.
5. Verfahren nach Anspruch 3, bei dem die multiplen Hybridgene eingeführt und als separate
Transkriptionseinheiten innerhalb einer einzelnen Zelle oder eines einzelnen Organismus
exprimiert werden.
6. Retrotransposon-Vektor zur Expression einer Fremdgen-Sequenz in Zellen oder Organismen,
erhältlich durch:
- Insertion der Fremdgensequenz in ein Retrotransposon-Genom, und
- Transfektion des rekombinanten, in der Transription aktiven Retrotransposon-Genoms
in eine Donorzelle, die die Retrotransposon-RNA oder -DNA in Form einer Partikel oder
eines Virions übertragen kann, die die Retrotransposon-Vektoren darstellen.
7. Retrotransposon-Vektor nach Anspruch 6, wobei der Vektor aus einem murinen Retrostransposon
VL 30 erhalten wird.
8. Retrotransposon-Vektor nach Anspruch 7, wobei der Vektor ausgewählt wird aus der Gruppe,
die aus Vektoren besteht, bei denen die Fremdgensequenz in Vorwärts-Orientierung vorliegt
(VLNPF), und aus Vektoren, bei denen die Fremdgensequenz in umgekehrter Orientierung
vorliegt (VLPNR), relativ zu VL30.
9. Retrotransposon-Vektor nach einem der Ansprüche 6 bis 8, wobei die Donorzelle ausgewählt
wird aus der aus psi2 und PA317 bestehenden Gruppe.
10. Retrotransposon-Vektor nach einem der Ansprüche 6 bis 9, wobei das Fremdgen durch
einen zellulären beweglichen genetischen Element-LTR(long terminal repeat)-Promoter
exprimiert wird.
11. Retrotransposon-Vektor nach einem der Ansprüche 6 bis 9, wobei das Fremdgen durch
interne Transkriptionseinheiten exprimiert wird, die in einem «heterozygoten» (chimeric)
zellulären beweglichen genetischen Element enthalten sind.
12. Retrotransposon-Vektor nach einem der Ansprüche 6 bis 11, wobei das Retrotransposon
zusätzlich genetisches Material umfaßt, das für mindestens einen dominanten selektierbaren
Marker codiert.
13. Retrotransposon-Vektor nach Anspruch 12, wobei der selektierbare Marker ausgewählt
wird aus der Gruppe, die Aminoglykosid-Phosphotransferase (eno, G4 18, APH), Dihydrofolat-Reduktase
(DHFR), Hygromycin-B-Phosphotransferase (HPH), Thymidinkinase (TK), Xanthin-Guanin-Phosphoribosyltransferase
(XGPRT, gpt), Chloramphenicol-Acetyltransferase (CAT) und Luciferase umfaßt.
14. Retrotransposon-Vektor nach einem der Ansprüche 6 bis 13, wobei das Fremdgen genetisches
Material umfaßt, welches für ein Peptid, einen Antikörper, ein Antigen, ein Hormon
oder einen Arzneistoff codiert, die jeweils normalerweise nicht in biologisch signifikanten
Mengen in der Zelle, dem Organismus oder der Spezies exprimiert werden.
15. Empfängerzellen, die nach dem Verfahren nach einem der Ansprüche 1 bis 5 erhalten
werden oder einen Vektor nach einem der Ansprüche 6 bis 14 enthalten.
16. Pharmazeutische Zusammensetzung, umfassend einen Retrotransposon-Vektor nach einem
der Ansprüche 6 bis 14 oder erhalten nach dem Verfahren der Ansprüche 1 bis 5.
17. Verfahren zur Herstellung eines Virions, welches einen Retrotransposon-Vektor nach
einem der Ansprüche 6 bis 14 umfaßt, wobei das Verfahren die Schritte umfaßt:
a) Isolierung eines interessierenden Gens,
b) Einführung des Gens in einen Vektor, der mindestens ein Retrotransposon umfaßt,
welches ein zelluläres bewegliches genetisches Element mit LTR's umfaßt, zur Bildung
eines Hybridgens,
c) Einführung des Hybridgens in eine Donorzelle, die zur Verpackung und Übertragung
des genetischen Retrotransposon-Elements in ein Virion fähig ist.
18. Virion, erhältlich durch das Verfahren nach Anspruch 17, umfassend einen Retrotransposon-Vektor,
welcher ein Hybridgen mit einem Retrotransposon umfaßt, welches ein zelluläres bewegliches
genetisches Element mit LTR's umfaßt.
1. Procédé pour le transfert et l'expression d'un gène dans des cellules, des organismes
ou des espèces, à l'exception des procédés pour le traitement de l'organisme humain
ou animal par thérapie, comprenant les étapes suivantes:
a) isolement du gène,
b) introduction dudit gène dans un rétrotransposon pour l'obtention d'un gène hybride,
c) introduction du gène hybride dans une cellule donneuse capable d'encapsidation
et de transmission du gène hybride dans un virion, constituant un vecteur de rétrotransposon,
d) transfert du virion dans une cellule receveuse, dans laquelle le gène hybride se
réplique par transcription inverse et est inséré dans le génome de la cellule receveuse
et
e) expression du gène hybride et criblage à la recherche du phénotype du gène hybride.
2. Procédé selon la revendication 1, dans lequel on obtient une préparation de cellules
receveuses contenant le gène hybride, avec des rendements élevés et utilisables, par
infection de cellules receveuses supplémentaires par les virions.
3. Procédé selon la revendication 1 ou 2, dans lequel des gènes hybrides multiples sont
introduits et sont exprimés sous forme d'ARN.
4. Procédé selon la revendication 3, dans lequel les gènes hybrides multiples sont introduits
et exprimés en tandem dans l'ARN.
5. Procédé selon la revendication 3, dans lequel les gènes hybrides multiples sont introduits
et exprimés sous forme d'unités transcriptionnelles distinctes dans une seule cellule
ou dans un seul organisme.
6. Vecteur de rétrotransposon pour l'expression d'une séquence de gène étranger dans
des cellules ou des organismes, pouvant être obtenu par:
- insertion de ladite séquence de gène étranger dans un génome de rétrotransposon,
et
- transfection du génome de rétrotransposon recombinant, à activité transcriptionnelle,
dans une cellule donneuse capable de transmettre de l'ARN ou de l'ADN de rétrotransposon
sous la forme de particule ou de virion qui sont les vecteurs de rétrotransposons.
7. Vecteur de rétrotransposon selon la revendication 6, dans lequel le vecteur est dérivé
d'un rétro-transponson murin VL30.
8. Vecteur de rétrotransposon selon la revendication 7, dans lequel le vecteur est choisi
dans l'ensemble constitué par des vecteurs dans lesquels la séquence de gène étranger
est en orientation directe (VLPNF), et des vecteurs dans lequels la séquence de gène
étranger est en orientation inverse (VLPNR), par rapport au VL30.
9. Vecteur de rétrotransposon selon l'une quelconque des revendications 6 à 8, dans lequel
la cellule donneuse est choisie dans l'ensemble constitué par psi2 et PA317.
10. Vecteur de rétrotransposon selon l'une quelconque des revendications 6 à 9, dans lequel
le gène étranger est exprimé par un promoteur de longue répétition terminale (LTR)
d'élément génétique cellulaire transposable.
11. Vecteur de rétrotransposon selon l'une quelconque des revendications 6 à 9, dans lequel
le gène étranger est exprimé par des unités de transcription internes incluses dans
un élément génétique transposable cellulaire chimère.
12. Vecteur de rétrotransposon selon l'une quelconque des revendications 6 à 11, dans
lequel le rétrotransposon comprend en outre du matériel génétique codant pour au moins
un marqueur sélectionnable dominant.
13. Vecteur de rétrotransposon selon la revendication 12, dans lequel le marqueur sélectionnable
est choisi dans l'ensemble constitué par l'aminoglycoside phosphotransférase (eno,
G4 18, APH), la dihydrofolate réductase (DHFR) l'hygromycine B phosphotransférase
(HPH), la thymidine kinase (TK), la xanthine-guanine phosphoribosyltransférase (XGPRT,
gpt), la chloramphénicol acétyltransférase (CAT) et la luciférase.
14. Vecteur de rétrotransposon selon l'une quelconque des revendications 6 à 13, dans
lequel le gène étranger comprend du matériel génétique codant pour un peptide, un
anticorps, un antigène, une hormone ou une substance active non normalement exprimée
dans la cellule, l'organisme ou l'espèce à des taux biologiquement significatifs.
15. Cellules receveuses obtenues par le procédé selon l'une des revendications 1 à 5 ou
contenant un vecteur selon l'une quelconque des revendications 6 à 14.
16. Composition pharmaceutique comprenant un vecteur de rétrotransposon selon l'une des
revendications 6 à 14 ou obtenu dans le procédé des revendications 1 à 5.
17. Procédé pour la production d'un virion comprenant un vecteur de rétrotransposon selon
l'une quelconque des revendications 6 à 14, ledit procédé comprenant les étapes suivantes:
a) isolement d'un gène d'intérêt,
b) introduction dudit gène dans un vecteur comprenant au moins un rétrotransposon
comprenant un élément génétique cellulaire transposable à longues répétitions terminales,
pour l'obtention d'un gène hybride,
c) introduction du gène hybride dans une cellule donneuse capable d'encapsidation
et de transmission de l'élément génétique de type rétrotransposon dans un virion.
18. Virion pouvant être obtenu par le procédé selon la revendication 17, comprenant un
vecteur de rétrotransposon comprenant un gène hybride avec un rétrotransposon comprenant
un élément génétique cellulaire transposable à longues répétitions terminales.